rocksdb/table/index_builder.h
Mike Kolupaev df38c1ce66 Add BlockBasedTableOptions::index_shortening (#5174)
Summary:
Introduce BlockBasedTableOptions::index_shortening to give users control on which key shortening techniques to be used in building index blocks. Before this patch, both separators and successor keys where shortened in indexes. With this patch, the default is set to kShortenSeparators to only shorten the separators. Since each index block has many separators and only one successor (last key), the change should not have negative impact on index block size. However it should prevent many unnecessary block loads where due to approximation introduced by shorted successor, seek would land us to the previous block and then fix it by moving to the next one.
Pull Request resolved: https://github.com/facebook/rocksdb/pull/5174

Differential Revision: D14884185

Pulled By: al13n321

fbshipit-source-id: 1b08bc8c03edcf09b6b8c16e9a7eea08ad4dd534
2019-04-22 08:20:35 -07:00

424 lines
17 KiB
C++

// Copyright (c) 2011-present, Facebook, Inc. All rights reserved.
// This source code is licensed under both the GPLv2 (found in the
// COPYING file in the root directory) and Apache 2.0 License
// (found in the LICENSE.Apache file in the root directory).
//
// Copyright (c) 2011 The LevelDB Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file. See the AUTHORS file for names of contributors.
#pragma once
#include <assert.h>
#include <inttypes.h>
#include <list>
#include <string>
#include <unordered_map>
#include "rocksdb/comparator.h"
#include "table/block_based_table_factory.h"
#include "table/block_builder.h"
#include "table/format.h"
namespace rocksdb {
// The interface for building index.
// Instruction for adding a new concrete IndexBuilder:
// 1. Create a subclass instantiated from IndexBuilder.
// 2. Add a new entry associated with that subclass in TableOptions::IndexType.
// 3. Add a create function for the new subclass in CreateIndexBuilder.
// Note: we can devise more advanced design to simplify the process for adding
// new subclass, which will, on the other hand, increase the code complexity and
// catch unwanted attention from readers. Given that we won't add/change
// indexes frequently, it makes sense to just embrace a more straightforward
// design that just works.
class IndexBuilder {
public:
static IndexBuilder* CreateIndexBuilder(
BlockBasedTableOptions::IndexType index_type,
const rocksdb::InternalKeyComparator* comparator,
const InternalKeySliceTransform* int_key_slice_transform,
const bool use_value_delta_encoding,
const BlockBasedTableOptions& table_opt);
// Index builder will construct a set of blocks which contain:
// 1. One primary index block.
// 2. (Optional) a set of metablocks that contains the metadata of the
// primary index.
struct IndexBlocks {
Slice index_block_contents;
std::unordered_map<std::string, Slice> meta_blocks;
};
explicit IndexBuilder(const InternalKeyComparator* comparator)
: comparator_(comparator) {}
virtual ~IndexBuilder() {}
// Add a new index entry to index block.
// To allow further optimization, we provide `last_key_in_current_block` and
// `first_key_in_next_block`, based on which the specific implementation can
// determine the best index key to be used for the index block.
// @last_key_in_current_block: this parameter maybe overridden with the value
// "substitute key".
// @first_key_in_next_block: it will be nullptr if the entry being added is
// the last one in the table
//
// REQUIRES: Finish() has not yet been called.
virtual void AddIndexEntry(std::string* last_key_in_current_block,
const Slice* first_key_in_next_block,
const BlockHandle& block_handle) = 0;
// This method will be called whenever a key is added. The subclasses may
// override OnKeyAdded() if they need to collect additional information.
virtual void OnKeyAdded(const Slice& /*key*/) {}
// Inform the index builder that all entries has been written. Block builder
// may therefore perform any operation required for block finalization.
//
// REQUIRES: Finish() has not yet been called.
inline Status Finish(IndexBlocks* index_blocks) {
// Throw away the changes to last_partition_block_handle. It has no effect
// on the first call to Finish anyway.
BlockHandle last_partition_block_handle;
return Finish(index_blocks, last_partition_block_handle);
}
// This override of Finish can be utilized to build the 2nd level index in
// PartitionIndexBuilder.
//
// index_blocks will be filled with the resulting index data. If the return
// value is Status::InComplete() then it means that the index is partitioned
// and the callee should keep calling Finish until Status::OK() is returned.
// In that case, last_partition_block_handle is pointer to the block written
// with the result of the last call to Finish. This can be utilized to build
// the second level index pointing to each block of partitioned indexes. The
// last call to Finish() that returns Status::OK() populates index_blocks with
// the 2nd level index content.
virtual Status Finish(IndexBlocks* index_blocks,
const BlockHandle& last_partition_block_handle) = 0;
// Get the size for index block. Must be called after ::Finish.
virtual size_t IndexSize() const = 0;
virtual bool seperator_is_key_plus_seq() { return true; }
protected:
const InternalKeyComparator* comparator_;
// Set after ::Finish is called
size_t index_size_ = 0;
};
// This index builder builds space-efficient index block.
//
// Optimizations:
// 1. Made block's `block_restart_interval` to be 1, which will avoid linear
// search when doing index lookup (can be disabled by setting
// index_block_restart_interval).
// 2. Shorten the key length for index block. Other than honestly using the
// last key in the data block as the index key, we instead find a shortest
// substitute key that serves the same function.
class ShortenedIndexBuilder : public IndexBuilder {
public:
explicit ShortenedIndexBuilder(
const InternalKeyComparator* comparator,
const int index_block_restart_interval, const uint32_t format_version,
const bool use_value_delta_encoding,
BlockBasedTableOptions::IndexShorteningMode shortening_mode)
: IndexBuilder(comparator),
index_block_builder_(index_block_restart_interval,
true /*use_delta_encoding*/,
use_value_delta_encoding),
index_block_builder_without_seq_(index_block_restart_interval,
true /*use_delta_encoding*/,
use_value_delta_encoding),
shortening_mode_(shortening_mode) {
// Making the default true will disable the feature for old versions
seperator_is_key_plus_seq_ = (format_version <= 2);
}
virtual void AddIndexEntry(std::string* last_key_in_current_block,
const Slice* first_key_in_next_block,
const BlockHandle& block_handle) override {
if (first_key_in_next_block != nullptr) {
if (shortening_mode_ !=
BlockBasedTableOptions::IndexShorteningMode::kNoShortening) {
comparator_->FindShortestSeparator(last_key_in_current_block,
*first_key_in_next_block);
}
if (!seperator_is_key_plus_seq_ &&
comparator_->user_comparator()->Compare(
ExtractUserKey(*last_key_in_current_block),
ExtractUserKey(*first_key_in_next_block)) == 0) {
seperator_is_key_plus_seq_ = true;
}
} else {
if (shortening_mode_ == BlockBasedTableOptions::IndexShorteningMode::
kShortenSeparatorsAndSuccessor) {
comparator_->FindShortSuccessor(last_key_in_current_block);
}
}
auto sep = Slice(*last_key_in_current_block);
std::string handle_encoding;
block_handle.EncodeTo(&handle_encoding);
std::string handle_delta_encoding;
PutVarsignedint64(&handle_delta_encoding,
block_handle.size() - last_encoded_handle_.size());
assert(handle_delta_encoding.size() != 0);
last_encoded_handle_ = block_handle;
const Slice handle_delta_encoding_slice(handle_delta_encoding);
index_block_builder_.Add(sep, handle_encoding,
&handle_delta_encoding_slice);
if (!seperator_is_key_plus_seq_) {
index_block_builder_without_seq_.Add(ExtractUserKey(sep), handle_encoding,
&handle_delta_encoding_slice);
}
}
using IndexBuilder::Finish;
virtual Status Finish(
IndexBlocks* index_blocks,
const BlockHandle& /*last_partition_block_handle*/) override {
if (seperator_is_key_plus_seq_) {
index_blocks->index_block_contents = index_block_builder_.Finish();
} else {
index_blocks->index_block_contents =
index_block_builder_without_seq_.Finish();
}
index_size_ = index_blocks->index_block_contents.size();
return Status::OK();
}
virtual size_t IndexSize() const override { return index_size_; }
virtual bool seperator_is_key_plus_seq() override {
return seperator_is_key_plus_seq_;
}
friend class PartitionedIndexBuilder;
private:
BlockBuilder index_block_builder_;
BlockBuilder index_block_builder_without_seq_;
bool seperator_is_key_plus_seq_;
BlockBasedTableOptions::IndexShorteningMode shortening_mode_;
BlockHandle last_encoded_handle_;
};
// HashIndexBuilder contains a binary-searchable primary index and the
// metadata for secondary hash index construction.
// The metadata for hash index consists two parts:
// - a metablock that compactly contains a sequence of prefixes. All prefixes
// are stored consectively without any metadata (like, prefix sizes) being
// stored, which is kept in the other metablock.
// - a metablock contains the metadata of the prefixes, including prefix size,
// restart index and number of block it spans. The format looks like:
//
// +-----------------+---------------------------+---------------------+
// <=prefix 1
// | length: 4 bytes | restart interval: 4 bytes | num-blocks: 4 bytes |
// +-----------------+---------------------------+---------------------+
// <=prefix 2
// | length: 4 bytes | restart interval: 4 bytes | num-blocks: 4 bytes |
// +-----------------+---------------------------+---------------------+
// | |
// | .... |
// | |
// +-----------------+---------------------------+---------------------+
// <=prefix n
// | length: 4 bytes | restart interval: 4 bytes | num-blocks: 4 bytes |
// +-----------------+---------------------------+---------------------+
//
// The reason of separating these two metablocks is to enable the efficiently
// reuse the first metablock during hash index construction without unnecessary
// data copy or small heap allocations for prefixes.
class HashIndexBuilder : public IndexBuilder {
public:
explicit HashIndexBuilder(
const InternalKeyComparator* comparator,
const SliceTransform* hash_key_extractor,
int index_block_restart_interval, int format_version,
bool use_value_delta_encoding,
BlockBasedTableOptions::IndexShorteningMode shortening_mode)
: IndexBuilder(comparator),
primary_index_builder_(comparator, index_block_restart_interval,
format_version, use_value_delta_encoding,
shortening_mode),
hash_key_extractor_(hash_key_extractor) {}
virtual void AddIndexEntry(std::string* last_key_in_current_block,
const Slice* first_key_in_next_block,
const BlockHandle& block_handle) override {
++current_restart_index_;
primary_index_builder_.AddIndexEntry(last_key_in_current_block,
first_key_in_next_block, block_handle);
}
virtual void OnKeyAdded(const Slice& key) override {
auto key_prefix = hash_key_extractor_->Transform(key);
bool is_first_entry = pending_block_num_ == 0;
// Keys may share the prefix
if (is_first_entry || pending_entry_prefix_ != key_prefix) {
if (!is_first_entry) {
FlushPendingPrefix();
}
// need a hard copy otherwise the underlying data changes all the time.
// TODO(kailiu) ToString() is expensive. We may speed up can avoid data
// copy.
pending_entry_prefix_ = key_prefix.ToString();
pending_block_num_ = 1;
pending_entry_index_ = static_cast<uint32_t>(current_restart_index_);
} else {
// entry number increments when keys share the prefix reside in
// different data blocks.
auto last_restart_index = pending_entry_index_ + pending_block_num_ - 1;
assert(last_restart_index <= current_restart_index_);
if (last_restart_index != current_restart_index_) {
++pending_block_num_;
}
}
}
virtual Status Finish(
IndexBlocks* index_blocks,
const BlockHandle& last_partition_block_handle) override {
if (pending_block_num_ != 0) {
FlushPendingPrefix();
}
primary_index_builder_.Finish(index_blocks, last_partition_block_handle);
index_blocks->meta_blocks.insert(
{kHashIndexPrefixesBlock.c_str(), prefix_block_});
index_blocks->meta_blocks.insert(
{kHashIndexPrefixesMetadataBlock.c_str(), prefix_meta_block_});
return Status::OK();
}
virtual size_t IndexSize() const override {
return primary_index_builder_.IndexSize() + prefix_block_.size() +
prefix_meta_block_.size();
}
virtual bool seperator_is_key_plus_seq() override {
return primary_index_builder_.seperator_is_key_plus_seq();
}
private:
void FlushPendingPrefix() {
prefix_block_.append(pending_entry_prefix_.data(),
pending_entry_prefix_.size());
PutVarint32Varint32Varint32(
&prefix_meta_block_,
static_cast<uint32_t>(pending_entry_prefix_.size()),
pending_entry_index_, pending_block_num_);
}
ShortenedIndexBuilder primary_index_builder_;
const SliceTransform* hash_key_extractor_;
// stores a sequence of prefixes
std::string prefix_block_;
// stores the metadata of prefixes
std::string prefix_meta_block_;
// The following 3 variables keeps unflushed prefix and its metadata.
// The details of block_num and entry_index can be found in
// "block_hash_index.{h,cc}"
uint32_t pending_block_num_ = 0;
uint32_t pending_entry_index_ = 0;
std::string pending_entry_prefix_;
uint64_t current_restart_index_ = 0;
};
/**
* IndexBuilder for two-level indexing. Internally it creates a new index for
* each partition and Finish then in order when Finish is called on it
* continiously until Status::OK() is returned.
*
* The format on the disk would be I I I I I I IP where I is block containing a
* partition of indexes built using ShortenedIndexBuilder and IP is a block
* containing a secondary index on the partitions, built using
* ShortenedIndexBuilder.
*/
class PartitionedIndexBuilder : public IndexBuilder {
public:
static PartitionedIndexBuilder* CreateIndexBuilder(
const rocksdb::InternalKeyComparator* comparator,
const bool use_value_delta_encoding,
const BlockBasedTableOptions& table_opt);
explicit PartitionedIndexBuilder(const InternalKeyComparator* comparator,
const BlockBasedTableOptions& table_opt,
const bool use_value_delta_encoding);
virtual ~PartitionedIndexBuilder();
virtual void AddIndexEntry(std::string* last_key_in_current_block,
const Slice* first_key_in_next_block,
const BlockHandle& block_handle) override;
virtual Status Finish(
IndexBlocks* index_blocks,
const BlockHandle& last_partition_block_handle) override;
virtual size_t IndexSize() const override { return index_size_; }
size_t TopLevelIndexSize(uint64_t) const { return top_level_index_size_; }
size_t NumPartitions() const;
inline bool ShouldCutFilterBlock() {
// Current policy is to align the partitions of index and filters
if (cut_filter_block) {
cut_filter_block = false;
return true;
}
return false;
}
std::string& GetPartitionKey() { return sub_index_last_key_; }
// Called when an external entity (such as filter partition builder) request
// cutting the next partition
void RequestPartitionCut();
virtual bool seperator_is_key_plus_seq() override {
return seperator_is_key_plus_seq_;
}
bool get_use_value_delta_encoding() { return use_value_delta_encoding_; }
private:
// Set after ::Finish is called
size_t top_level_index_size_ = 0;
// Set after ::Finish is called
size_t partition_cnt_ = 0;
void MakeNewSubIndexBuilder();
struct Entry {
std::string key;
std::unique_ptr<ShortenedIndexBuilder> value;
};
std::list<Entry> entries_; // list of partitioned indexes and their keys
BlockBuilder index_block_builder_; // top-level index builder
BlockBuilder index_block_builder_without_seq_; // same for user keys
// the active partition index builder
ShortenedIndexBuilder* sub_index_builder_;
// the last key in the active partition index builder
std::string sub_index_last_key_;
std::unique_ptr<FlushBlockPolicy> flush_policy_;
// true if Finish is called once but not complete yet.
bool finishing_indexes = false;
const BlockBasedTableOptions& table_opt_;
bool seperator_is_key_plus_seq_;
bool use_value_delta_encoding_;
// true if an external entity (such as filter partition builder) request
// cutting the next partition
bool partition_cut_requested_ = true;
// true if it should cut the next filter partition block
bool cut_filter_block = false;
BlockHandle last_encoded_handle_;
};
} // namespace rocksdb